High-temperature synthetic lubricious composition

ABSTRACT

Synthetic lubricant compositions having several unique performance advantages over known lubricants are provided. The presently claimed compositions are either clear or translucent to white and non-staining. In addition, they have absolutely no odor, are non-toxic, and all ingredients are USDA approved. Finally, they retain their high-performance characteristics through a temperature range of about −40° F. up to about 550° F.

This application claims the benefit of Provisional Application No. 60/132,827 filed May 6, 1999.

FIELD OF THE INVENTION

This invention relates to high-temperature synthetic lubricious compositions that are suitable for use in operations including the processing and preparation of foodstuffs.

BACKGROUND OF THE INVENTION

A wide variety of industrial and mechanical apparati require lubrication of their moving parts to prevent premature wear and failure of the equipment. Natural lubricants, such as animal and vegetable fats, oils, and greases have been known for millennia. However, as the industrial age arrived, these were found not to be suitable in the high temperature, high pressure conditions experienced in the machinery being developed. Petroleum-based lubricants have been known for over a century and have been developed for many such applications. However, the cost of locating, extracting, and refining crude oil to manufacture these lubricants, as well as limitations on their performance and durability, led to the development in this century of synthetic lubricants.

Synthetic lubricants have been developed to meet a variety of needs and have in the last twenty years gained in both their technical performance and their popularity. However, most synthetic lubricants include ingredients that are not suitable for certain applications, e.g., for use in food processing and preparation. It is highly desirable to have a cost-effective, high-performance lubricant that is approved for such uses by the United States Department of Agriculture.

In addition, process conditions play a significant role in determining both the performance and commercial acceptance of a synthetic lubricant. If the heating conditions during preparation of the lubricant are not optimal, e.g., if the lubricant is heated too much or too little or at the wrong point in the process, the lubricant can have an undesirable color or smell. One popular ingredient, Irgalube, can impart a sweet smell that is not always desirable. However, omitting this ingredient to eliminate the odor can alter the performance characteristics of the lubricant. In addition, replacement with DuPont's Teflon® may result in a lubricant that has an uneven consistency. Replacement with Krylon® (liquid Teflon® in an isopropyl base) may resolve the consistency problems, but the isopropyl doesn't react well at high temperatures.

SUMMARY OF THE INVENTION

The present invention relates to synthetic lubricant compositions and methods for their manufacture and use. The compositions comprise mixtures of hydrogenated poly-α-olefins, styrene-ethylene/propylene copolymer, petroleum hydrocarbons, fumed silica, propylene glycol, and PTFE.

A critical element to the successful preparation of compositions in accordance with the present invention is the use of fine-grained PTFE that is easily mixed into the composition. Use of such PTFE not only solves the problem of an undesirable smell but also results in a nice appearance to the product. In addition, the resultant compositions perform at a much higher level than known compositions.

The presently claimed synthetic lubricant compositions provide several unique performance advantages over known lubricants. The presently claimed compositions are either clear or translucent to white and non-staining. In addition, they have absolutely no odor, are non-toxic, and all ingredients are USDA approved. Finally, they retain their high-performance characteristics through a temperature range of about −40° F. up to about 550° F.

DRAWINGS

FIG. 1 shows the technical specifications for synthetic lubricious compositions of the present invention.

DETAILED DESCRIPTION

The present invention may be embodied in a variety of formulations. One feature of the invention, putting high heat on the poly-α-olefin oil, enables the consistent production of a high-quality composition; even if you overheat the batch, you still won't burn the oil.

The ranges of each component of the composition are as follows:

Ingredient CAS Number wt % 1.) Hydrogenated Poly-α-olefins 68037-01-4 33-81 2.) Styrene-Ethylene/Propylene Copolymer 68648-89-5 2-4 3.) Petroleum Hydrocarbons 8042-47-5  1-60 4.) Fumed Silica 112945-52-5  5-10 5.) Propylene Glycol 029434-03-5 2-5 6.) PTFE 79070-11-4 1-5

Optionally, 2-5 wt % polybutane (CAS No. 9003-29-6) may be added. Regardless of the amounts of individual ingredients used, the liquid portion of the composition equals about 90%.

Example 1

A 10% by weight Shelvis solution was prepared using a 55 gallon drum with a high-temperature heat belt. 375 lbs of Amoco Dynacyn 168 (poly-α-olefin) was pre-heated to 200-240° F. 40 lbs Shelvis-50 (styrene-ethylene/propylene copolymer) powder was added to the pre-heated poly-α-olefin and the mixture was mixed under low agitation for approximately 3 hours with a 20 hp Schold mixer until the powder was melted. The liquid was strained through a 100μ mesh strainer (filter bag).

Example 2

PTFE paste was prepared by adding 40 lbs of PTFE powder to 20 lbs Amoco Dynacyn 168 (poly-α-olefin) and grinding the mixture together at 140° F. until it formed a paste.

Example 3

A synthetic high-temperature grease was prepared as follows. 110 lbs of the 10% Shelvis solution was mixed with 50 lbs Dynasyn 168 (poly-α-olefin), and 105 lbs mineral oil and the mixture was preheated to 125° F. 11 lbs Indepol 300 (polybutane), 8 lbs PTFE paste, 18 lbs fumed silica M-5, and 10 lbs propylene glycol 2025 were slowly sequentially added as the mixture was mixed. This yielded 312 lbs of the composition.

Example 4

Ingredient CAS Number wt % 1.) Hydrogenated poly-α-olefins 68037-01-4 48 2.) Styrene-Ethylene/Propylene Copolymer 68648-89-5 3.5 3.) Petroleum Hydrocarbons 8042-47-5 33 4.) Polybutane 9003-29-6 3.5 5.) Fumed Silica 112945-52-5 7 6.) Propylene Glycol 029434-03-5 3 7.) PTFE 79070-11-4 2

A high-temperature, synthetic lubricant composition was prepared as follows. Hydrogenated poly-α-olefins were heated to about 240° F. Styrene-ethylene/propylene copolymer was added and mixed at low agitation until dissolved (melted) and the solution was strained through a 100 micron mesh filter bag. Petroleum hydrocarbons and polybutane were slowly added and mixed for 15 minutes. PTFE was added and the composition mixed for 10 minutes and the temperature was reduced to 125° F. gradually in order to maintain the composition's viscosity. At this point, it is important to verify that the temperature of the composition is 125° F. Fumed silica was then slowly added, making sure not to create too much dust. Finally, polypropylene glycol was added and the composition was mixed thoroughly and run through a Cornell Versator.

While the present invention has been described in terms of specific methods and compositions, it is understood that variations and modifications will occur to those skilled in the art upon consideration of the present invention. Numerous modifications and variations in the invention as described in the above illustrative examples are expected to occur to those skilled in the art. 

What is claimed is:
 1. A high-temperature, synthetic lubricant composition comprising 33-81 wt % hydrogenated poly-α-olefins, 2-4 wt % styrene-ethylene/propylene copolymer, 1-60 wt % petroleum hydrocarbons, 5-10 wt % fumed silica, 2-5 wt % propylene glycol, and 1-5 wt % PTFE.
 2. The high-temperature, synthetic lubricant composition as claimed in claim 1 further comprising 2-5 wt % polybutane.
 3. A method for manufacturing a high-temperature, synthetic lubricant composition, the method comprising the following steps: (a) heating 33-81 wt % hydrogenated poly-α-olefin to about 240° F.; (b) adding 2-4 wt % styrene-ethylene/propylene copolymer to said heated hydrogenated poly-α-olefin; (c) mixing the above ingredients under low agitation until the styrene-ethylene/propylene copolymer is dissolved; (d) straining the resultant solution through a 100 micron mesh filter bag; (e) slowly adding 1-60 wt % petroleum hydrocarbons and mixing the composition for an additional 15 minutes under low agitation; (f) adding 1-5 wt % PTFE and mixing the composition for an additional 10 minutes under low agitation; (g) verifying that the temperature of the composition is 125° F. (h) slowly adding 5-10 wt % fumed silica to the above mixture; (i) Adding 2-5 wt % polypropylene glycol to the above mixture while mixing the composition under low agitation; (j) filtration of the thoroughly mixed composition through a Cornell Versator.
 4. The method as claimed in claim 3 further comprising addition of 2-5 wt % polybutane in step (e). 